DE3605060A1 - CONNECTOR FOR CONNECTING AN OPTICAL CABLE TO A PHOTO CONVERTER - Google Patents

Description

ALLEN-BRADLEY COMPANY , Milwaukee, Wisconsin, VStA

Connector for connecting an optical cable to a photo transducer element

The invention relates to optical fiber connectors and is particularly concerned with a connector for termination a fiber optic cable or optical cable to a photo transducer element.

Connector for connecting optical cables to photo transducer elements, for example optoelectronic detectors and emitter, must be able to provide very precise alignment between the optical fiber and the Manufacture transducers. An alignment between an optical fiber with a diameter of about 200 / µm and an area provided on the photo converter with a diameter of about 1100 / µm.

In some industrial applications there must be a large number of connections or connections between a Conductor cables and a device are made. For example, in applications involving solid-state control devices Can make use of the connection between input / output circuit boards and external devices comprise hundreds or even thousands of connections. The circuit boards are typically in a rack supported, to which a connector is attached, which separates from a connection or a terminal Disengaged or disengaged position in a connection or a connection producing engagement or Switch position can be moved to produce a large number of connections or connections. Such designs work very well when it comes to connecting electrical conductors together. In contrast it has not been possible to date with an economically justifiable effort to reduce the dimensions of the

Stells so master, that the for fiber optic connectors required dimensional accuracy is achieved.

Despite the high Ausrichtungsgenauigk @ it ₉ required for producing Lichtleltfaserverbinaungen, yet there is often a desire "to create an easily separable optical fiber link ₀ Moreover, it is rtjünscht in some applications ©, with a single connector both optically © and electrical connections to manufacture. Furthermore, depending on the particular application, there is the need to provide numerous connections of each of these two types of connection. The requirements to be placed on such a connector are very high because the electrical connections are a fixed, rigid connection and the optical connections are extremely high Require accuracy _o In addition, the connector must be able to be manufactured relatively inexpensively in industrial applications _o

Optical cables typically become cheaper with optical cables Contacts completed. The production of such optical contacts is a special technique in itself itself. But there are numerous different companies

[Selling Optical Contacts] Some conventional connectors require extremely specialized contacts in order to achieve the necessary alignment accuracy. The commercially available contacts cannot be used for these connectors «. The difficulties and expense involved ve to the provision and use of these special contacts ^ Tbunden is even could act on the other linsatz the Lichtleitfaseroptik daunting total ₀

Easy assembly and l@iete.te maintenance of the connector is also an essential face

Period. With the conventional connectors with special contacts, especially with connectors that are used as single connectors If you want to operate some contacts, it is difficult to install and / or replace the cables. While cable replacement is not an essential consideration in laboratory applications, at industrial applications the fiber optic cables are more vulnerable to damage. A simple Replacing the cables leading to the connector can therefore be significant and for ease of maintenance play a role.

According to the invention there is provided a connector which is used for connecting an optical cable, including at least one optical fiber with an optical contact as a termination, is used on a photo transducer element. The connector has a swivel, swivel, tilt or swivel component that is capable of the optical To hold the contact in such a way that the terminal end of the contact is attached to an inner side of this Adjacent component, which in the following is only referred to as a pivoting or rotating component. A connector body defines a cavity which loosely receives the rotary member and which allows the rotary member is movable within the connector body. The photo transducer element is mounted in a base so that that the photo transducer element is accessible from an inner side of the base part. On the inner side of the The rotating component and on the inner side of the base part, surfaces that are matched to one another are formed, which, through mutual guidance, serve to establish the optical contact and the photo transducer element with one another align when the connector body is in an engaged or engaged position adjacent to the base is moved in which the connection or connection is made. Between the connector body and the Rotary member is provided a pretensioning device that

a self-alignment of the rotating component with respect to the base part and which allows the rotating component in the direction presses on the base. Finally, means are also provided that the connector main piece in his Secure the engaged or switched-on position. The connector according to the invention thus formed allows an accurate one Alignment between the optical contact and the photo converter element and is also on the optical Easily separable interface between the contact and the photo transducer element.

The optical fiber connector according to the invention can very easily be incorporated into a group or bank of similar optical fiber connectors be incorporated by having a plurality of the rotating components in a single connector body is provided and likewise a plurality of corresponding basic parts, preferably in one one-piece basic module is integrated. You can then make numerous connections or connections by that the connector main piece is brought into its connected position. Since the invention is based on commercially available Optical fiber contacts can be applied and each contact on its own and easily on one at a time Rotary component can be mounted, such a connector is characterized by simple and easy maintenance «

A preferred development consists in that the connectors according to the invention are included in a pivot arrangement. The basic parts are attached to circuit boards that are held in a frame. A pivot arm including the connector body and the pivoting components is pivotally attached to the frame and can be pivoted from a disengaged or disengaged position in which the pivoting components are not engaged with the bases to the engaged or detached position. The connector body and frame see a general alignment between ami

Rotary components and the base divide before when the connector main piece is pivoted into the switch-on position. The coordinated surfaces on the inner Sides of the rotating components and base parts ensure the final alignment, with the optical contact and the photo transducer element can be brought into precise alignment with one another.

A connector designed according to the invention can, in addition to the optical connections, also Provide easily separable electrical connections. The alignment capability provided by the connector body also directs electrical contacts fixedly attached to the connector body with their associated ones Mating contacts from, with a firm engagement between the contacts is made. Although through the intervention of the electrical contacts at their associated mating contacts, the stiffness of the connector main piece is increased, the rotating members within the connector body can move around the optical contacts align with the photo transducer elements.

In a preferred development, the electrical contacts are in a number of transducer arrangements included, easily separable optical interfaces and easily separable electrical interfaces in one provide a single optical connector. Each transducer assembly is for connection to an optical fiber connector suitable and includes a photo transducer element and a set of electrical contacts that connect to the Electrodes of the light guide transducer element are connected. In the swing arm construction, the electric ones are Contacts suitable for engagement with electrical contacts provided on the circuit board when the Swivel arm is brought into its on position. This type of connector is used in particular where where optical connections especially with external devices

are desired and some electrical connections at the connector interface are preferred.

/ \ Main object of the invention is thus to provide an optical fiber connector which ensures accurate alignment between an optical fiber and a phototransducer element. This object is essentially made possible by the provision of the pivoting or rotating member which serves to receive optical contact and which aligns itself within the connector main body with the base part carrying the photoconductor element.

The connector to be created should also be suitable for being inserted into a bank of similar connectors can be included or integrated. This is ensured by the fact that every swiveling or rotating component independent of the other pivoting or rotating components within a single connector body is movable and can align itself with the associated base part.

The connector to be created should ultimately also be easy and simple to maintain. this will essentially achieved in that each optical contact is detached and fastened individually in a simple manner from the pivoting or rotating component assigned to it can be.

The connector to be created should also do without highly specialized optical contacts ^ so that for commercially available contacts can be used. This goal is also achieved by the fact that the otherwise Usual alignment function of the optical contact itself on the rotary or rotation device provided according to the invention Pivoting component is transmitted to which the optical contact can be attached in a simple manner and which the

Alignment function takes over together with the base part carrying the photo transducer element.

The connector 5 to be created according to the invention or a group of such connectors should also be so be designed that a faster and easier connection of the optical fibers to the photo transducer elements with high Alignment accuracy is enabled. To achieve this goal, the connector is designed as a swivel arm at.

An optical fiber connector to be created according to the invention is intended to be a single connector despite its design make both optical and electrical connections or connections in a simple and easy manner and can separate. This goal is essentially achieved in that the connector main piece is a coarse Alignment provides for the electrical contacts of the transducer assemblies with their associated mating contacts to align and also to align the rotating or swiveling components with the basic parts. It also takes place then fine alignment between the optical contacts and the photo transducer elements by the one on top of the other coordinated surfaces on the rotating or swiveling components and the base parts.

Another object of the invention is to provide a connector for optical connection of optical cables or Fiber optic cables to photo transducer elements and for electrical connection of other optical or fiber optic cables to electrical contacts. To this end, transducer assemblies are provided in a connector which also includes the rotating or pivoting components that mate with the base parts.

Finally, according to the invention, a connector is to be created which can also be produced economically. This object is achieved in that the connector is capable of being "is used ® ± ner overall construction, the plastic mis be prepared ormteilen karaio

In summary, according to the invention, a connector for connecting an optical cable to a photo transducer element is created which is essentially characterized by the following features. In a main piece of the connector a Breli- or pivoting component is movably housed, Bsr © ptische contact is held in the pivoting component so that it adjoins with its optical connection end on © ine Imienseite of the pivoting component. The photo transducer element is held in a basic component in such a way that it is accessible from an inside of the basic part. The inner sides of the pivoting component and the main component have coordinated guide surfaces which, when the connector is connected to a device carrying the plioto transducer element, align the contact connection end of the optical cable and the photo transducer element with one another. In the switched-on state, a pretensioning device provided between the connector main piece and the pivoting component presses the pivoting component together with the optical contact in the direction of the base component carrying the photoconverter element. In this way a precise and easily detachable connection between the optical contact and the photo converter is created. Preferably, the connector is in a mounted on the device Schwenkarmkonstrukti © © lalbezogen a _β

The invention is described below with reference to Drawings explained by way of example. It shows:

F I G. 1 is a perspective view of a control device in which the optical fiber connector according to FIG of the invention are provided.

F I G. 2 is a sectional view in a plane $ along the line 2-2 of FIG. 1, 10

F I G. 3 is a front view of part of the control device according to FIG. 1,

F I G. 4 is a sectional view in a plane along the line 4-4 of FIG. 3 in a state at with a fiber optic cable mounted in place,

FIG. 5 is a perspective view of a Swivel arm frame for the connector,

F I G. 6 a rear view of a basic module for the connector;

F I G. 7 is a side view of the basic module according to FIG. 6,

F I G. 8 is a sectional view in a plane along the line 8-8 of FIG. 6, 30th

FIG. 9 is a sectional view in a plane along the line 9-9 of FIG. 3 in a state where an optical fiber cable is mounted in place,
35

F I G. 10 is an assembled perspective view of a connector body and rotating member for the connector,

F I G. 11 a side view of the frame according to FIG. 5 and

FIG. 12 a sectional view in © isass »plane along line 12-12 of FIG. 9.

A preferred exemplary embodiment of the invention is to be described in connection with a typical application in the field of control and regulation technology. FIG. 1 shows a control device 10 with three circuit boards 11 which are accommodated in a frame 12. The controller was seeking a greater number of circuit boards aiifif3issn _s and the special type of arrangement and mounting of the circuit boards in the control unit can be implemented is Bassigfacher way.

The frame 12 has a frame 13 c-nf ₉ in which two upright side walls 14 and 15 gel. These two side walls are di ^ ete with one another. two upper support rods 16 and two lower support rods 17 connected. A group of upper guide rails 18 are connected to the upper support rods 16 and a group of further guide rails 19 are connected to the lower support rods 17. Each of the guide rails 19 is provided with a slot which is used to accommodate the respective upper or lower edge of a circuit board 11. The guide cables are arranged along the respective support rods 16 and 17 at regular intervals from one another Torges3! I®ii _s that the circuit boards 11 are held between the sides 15 and 15 close to one another in essentially parallel planes.

FIG. 2 it can be seen, DAB dl © Bokm plates 11 have a substantially reehtediffesigs Wosz. Your front and rear edges w®f1sm £ ^: slz let «

right to their top and bottom edges. The rear edge of each circuit board 11 is received in a set of male parts 20a attached to a nut plate 20b which is at the rear of the frame 13 is provided. One according to the invention formed connector is provided adjacent to the lower half of the leading edge of each circuit board 11. A control unit of the ones considered here Type, whose circuit boards only have electrical interfaces, is from the U.S. Patent 4,151,580 is known. Reference is hereby expressly made to the entire content of this publication *

Each connector includes a pivot arm 21.

FIG. 1 reveals three pivot arms 21, one for each circuit board 11. The Swivel arms 21 are pivotally attached to the front lower support rod 17. Furthermore, the swivel arms 21 mounted on the support rod 17 in the space between the guide rails 19 so that the axial displacement the pivot arms 21 and the guide rails 19 on the support rod 17 is limited. In this context it may be appropriate to use spacer sleeves or the distance between the circuit boards so to be reduced far so that the axial displacement of the pivot arms 21 is restricted even more. Everyone Swivel arm 21 is from a disengagement or disconnected position that separates the connection, in which the one shown in FIG. The pivot arm 21 shown on the left is in an engagement or connection position that establishes the connection pivotable, in which the two in FIG. 1 pivot arms 21 shown on the right are located.

Each pivot arm 21 includes a connector body 22, four pivot members or pivot members 23, the attached to the upper part of the main body 22, and four transducer assemblies 24 attached to the lower part of the

Main piece 22 are attached. Each of the Bre & components 23 and each of the transducer assemblies 24 is gum mount a fiber optic cable 25 suitable ^ t? ie it in FIG. 1 is shown for the rightmost swing arm.

As FIG. 4 ViBgSk ₉ , each transducer arrangement contains a holder 29 serving for an active component and a photoconductor @ p ° component, for example a light emitter 30. The emitter 30 is housed tightly in a bore 31 in the holder. The upper surface of the emitter 30 is preferably close to a shoulder 32 at a © _s that the position of the emitter with respect to the top ö @ r holder is accurately determined 29th The emitter 30 has a set of electrodes 33 which are curved in such a way that they extend outward through holes 34 provided in the mounting bracket 29 © n Saitter holds firmly in place and locks it at the bottom. Active Components receiving brackets have ^ already a shed in emitter _s are commercially available and can be purchased from different manufacturers, such as Hewlett-Packard Corporation.

The holder 29 carrying the active component is fastened to a connector housing 35. The fastening can be carried out in various ways, for example by gluing with a suitable adhesive or by ultrasonic "" welding. A connecting or connecting device, for example a circuit _{board 36 ß} is in the recess of the connector housing 35 below the figure eight, and the emitter electrodes 33 are with § © siga © t © n mini

Leads soldered on the circuit board 36 or electrically connected therewith in another suitable manner. These connections on the circuit board 36 are conductive with the electrodes of a set of electrical spring contacts 38 in connection. The contact electrodes extend through openings 39 provided in the connector housing 35 into a contact jacket receiving the contacts 38 40. The contact jacket 40 is formed with a recess in which there is a captive Nut 41 is located, firmly attached to the connector housing 35, for example by gluing, ultrasonic welding or similar.

Each transducer assembly 24 assembled in this way is attached to a swing arm frame 23, which is part of the connector body 22. FIG. 5 it can be seen that the swivel arm frame 43 with each other spaced triangular ribs 44 is equipped. These ribs fit with beveled Corners (not shown) of connector housing 35 together so that when assembled, each transducer assembly 24 assumes an exact position along the swivel arm frame 43. On the connector housing 35 are tongues 45 (FIGS. 1 and 4) which form shoulders 46 are also provided. The shoulders 46 suitably span one Corner 47 of the swing arm frame 43. A screw 48 extends through a hole 49 in the swing arm frame 43 and engages the captive nut 41, so that the transducer assembly 24 on the frame 43 in more detail Alignment is firmly attached.

One of the fiber optic cables 25 is connected to each of the transducer assemblies in the following manner 24 connected. The cable 25 is first terminated with a suitable optical contact 51. These optical contacts are commercially available, and the process of attaching the cable connector

Connection or cable termination is generally specified precisely by the respective manufacturer. Further details on this pillow are therefore omitted. It is sufficient to note that the optically © contact 51 has a terminal end 52, in AEM at least one optical fiber 54, the Lichtl it © © nde component of the cable 25 is being positioned very precisely in the center of the contact 51st B © r contact 51 is received by a tightly fitting hole 53 Is. <Ä © F the active component-carrying holder 29 * The hole 53 extends to the emitter 30 and runs concentrically to the hole 31 so that the fiber 54 in the middle or at least very close to the center of the emitter 30.

Terminal end 52 is preferably on the emitter 30, although for most mifestangs too a small gap is acceptable. Contact 51 is on the transducer arrangement 24 with the aid of a union nut 55, which is screwed onto a thread formed on the bracket 29 »A The flange 56 formed on the contact is caught between the union nut 55 and the end of the holder 29, so that the contact 51 is securely held in the holder 29.

The connection between the optical contact 51 and the transducer arrangement 24 is not easily separable. The connection is thereby established ₉ when the contact 51 is inserted into the bore 53 and the union nut 55 is tightened, Ms gie alch tightened against the flange 56. The separation of the Y@rMnd.ung is done in the opposite way. If some connections have to be made or disconnected, the associated handles are consuming.

In contrast, the connection between the transducer assembly 24 and the circuit board 11 can be very high can be easily established and interrupted. If a swivel arm is swiveled into its switch-on position, occurs the front edge of the circuit board 11 into the contact jacket 40, and the electrical contacts 38 engage on contact pads 57 (FIG. 1), the along the edge of the circuit board (on the opposite side visible in FIG. 1) Side) are printed and aligned with the associated contacts 38.

The component mount 29 ', the connector housing 35 and the swing arm frame 43 are all preferred molded from plastic, for example by pressing, casting or injection molding. The dimensional Accuracy required to align contacts 38 with contact pads 57 can be very easily through the frame 12, the circuit board 11, the swing arm frame 43 and the transducer assemblies 24 are provided. The much higher accuracy which is required to align the optical fiber 54 with the emitter 30 is also used produced in a simple manner by the optical contact 51 and the holder 29 for the active component. This overall construction thus provides a relatively inexpensive optical connector that provides an easily separable electrical interface.

However, easily separable electrical connections are undesirable in some applications. Although the flow of current to and from most light-emitting photo-transducers is sufficient to generate the electrical Maintaining contact connection is still the case, for example, with light detector photo transducers Current flow is often too low to ensure electrical contact

connection to surmount safely. To remedy this To create a problem, the connector body 22 and each pivot member 23 preferably form part of one Optical fiber connector that connects an optical fiber and provides an easily separable optical interface to a photo transducer element.

The optical fiber connector contains a base part 58 for each rotating component 23. Four base parts 58 are formed in one piece with a basic module 59, as shown in FIG. 6 to 9 can be seen. The basic module 59 is fastened in a two-piece housing 61, with the aid of recesses provided on the basic module formed edges 60 which fit into corresponding grooves in the housing 61. The basic module 59 and the Housing 61 could also be made in one piece. On the other hand, the base parts 58 could directly the circuit board 11 can be attached. In the grand module 59 there is a groove 62 that is in between the base parts 58 is bounded by two ribs 63 and which form the edge of a circuit board 64 (FIG. 9) which is accommodated in the housing 61. The housing 61 is in turn on the circuit board 11 fixed so that between the circuit board 11 and the circuit board 64 suitable connections easily can be produced.

As one can see in particular FIG. 9, a photoconverter element, for example a detector 65, finds a tightly fitting receptacle in a cylindrical bore 66 in each base part 58. A slot (FIG. 6) can be provided in each base part 58 in order to accommodate a projection (not shown) and in this way to align electrodes 69 provided on detector 65 with respect to circuit board 64 in a suitable manner. The upper surface of the detector is adjacent to a shoulder 70 on the means ₉

a bore 71 formed in the base part 58 and having a smaller diameter is provided. The detector 65 is thus accessible from an inner side 72 of the base part 58. The one below the detector located space, which is slightly larger in diameter than a flange 73 of the detector, contains a Potting compound to close the detector and hold it in place. The detector electrodes 69 are preferably soldered to the circuit board 64 with suitable connections. Soldering the electrodes ensures the integrity of the interface between the electrodes and the circuit board what of It is important that the detector current can be very low.

As can be seen from FIG. 9 to 11, there are four semicircular recesses in the swivel arm frame 43 74 formed, which serve to receive the rotating components. The rotating members 23 are within the recesses held back or secured by means of a holding rod shown in FIG. The handrail 75 together with the swivel arm 43 forms the connector main piece 22. Four semicircular recesses 76, which are mirror images of the recesses in the swing arm frame 43, are in the Holding rod 75 is provided so that the recesses 76 and 76 together have four cavities or cavities in the Form connector main piece 22 when the swing arm frame 43 and the support rod 75 are assembled.

The support rod 75 has two in its central portion Pegs 77 and a peg 78 on each of their end sections, each of which is located in peg holes 79 and 80 which are formed in the swing arm frame 43 so as to allow for precise alignment to provide between the support rod 75 and the swing arm frame 43. The support rod 75 is on Swing arm frame 43 in any suitable manner

attached, for example by gluing ^ ultrasound welding or the like.

Within one of the cavities, which are formed by the recesses 74 and 76 in the connector main piece 22, there is thus in each case a rotating component 23 which could also be referred to as a pivoting or articulating component. FIG. 9 shows that each of the recesses 74 and 76 and thus also each of the cavities formed by these recesses follows the general contour of the rotary component 23. Each Dpehbauteil 23 is captured within its associated cavity and cannot be lost. On the other hand, each Brehbauteil 23 sufficiently great freedom of movement ^ bo that it is principal part 22 can move within the cavity relative to the connector-=.

A preloading or pretensioning device 81, preferably in the form of a compressible O ~ ring, which consists, for example, of an elastic polymerisation product or elastomer, is between a upward and outward looking shoulder 82 on the rotary member 23 and one downward and inward looking Shoulder 83 arranged in the region of the cavity in the connector main piece 22. The pretensioner 81 has the tendency to center the rotary member 23 within the cavity and the rotary member 23 towards the base part 58 to press. FIG. 12 one can see that each recess 74 and 76 has a slot 84, which is slightly raised on both sides by two Lugs 85 is limited. The rotating member 23 has two ribs 86 on opposite sides, which are loose protrude into the slots 84 to allow a rotational movement of the rotary member 23 relative to the connector body 22 to prevent.

In the rotary component 23 there is a bore 89 into which a contact 51 fits closely or fits snugly is used. The rotating member 23 has a thread, which allows the contact 51 with With the aid of a union nut 55 in the rotating component 23 can be attached. The terminal end 52 of the contact extends beyond the end of the bore 89 and adjoins an inner side 91 of the rotating component 23.

Mating surfaces on the inside 72 of the base 58 and on the inside 91 of the Rotary members 23 each have beveled or frustoconical Sections 95 and 96 and cylindrical sections 97 and 98. If the pivot arm 21 in pivoted to its engaged or switched-on position, each rotary component 23 is in general alignment with its associated base part 58. A groove 99 formed in the swivel arm frame 43 takes the edge of the circuit board 11 and supports the alignment. When the rotating member 23 is the base member 58 approaches, the frustoconical surface 95 on the base component guides the cylindrical surface 98 of the rotating component onto the cylindrical surface 97 of the basic component. This second state of Alignment is possible because the pivot member moves freely within connector body 22 can. The fit between the cylindrical surfaces 97 and 98 is either a light press fit or a tight fit or at least so tight that a diameter-wise fit Alignment between the two surfaces is ensured. The frustoconical Surfaces 95 and 96 may also, or instead, be designed to mate with one another, to make good alignment. Preferably, the connecting end 52 of the contact 51 strikes Window 100 at the top of the detector 65 to permit movement of the rotating member 23 towards the

Stop the detector. As soon as the connection end 52 rests on the detector 65, a further movement results of the main contact piece 22 in the direction of the edge parts 58 only in a compression of the Vorspaxmeinriehtung 81.

The connector main piece 22 (including the swing arm _{frame 43 and the support rod 75) 9,} the rotary member 23 and the base module 50 are all molded from plastic, for example by pressing, molding, injection molding or the like. The phototjandler detector 65 has a circular active area 103 (FIG. 9) which is large with respect to the diameter of the light-guiding core of the fiber 54, so that a certain dimensional deviation can be allowed because the active area 103 is not completely with it of the fiber 54 must be centered so that an acceptable proportion of the light emerging from the fiber falls on the active area. A suitable adaptation of the fiber 54 and the active area 103 can result in a permissible dimensional deviation which is greater than the possible dimensional deviation when the rotating components 23 and base parts 58 formed from plastic are veneered.

Precision process for making ύοώ. Molded parts made of plastic lead to tolerances of less than ± 40 μm. With this accuracy, the center-to-center tolerance is between the bore 89 and the bore 66 at ineinandergepaßtem rotary member 23 VND base 58 about 75 t / um. A slight slope of the bore 66 results in a diameter tolerance of approximately 25 μm, and the diameter tolerance of the bore 89 is approximately 50 μm. The total center-to-center tolerance of a nominally sized detector 65 and contacts 51 is therefore no more than * 850 / µm. Obgleieb. slide

Tolerances of some commercially available fibers, contacts and detectors are normally not available, they can be estimated in combination to be no more than + 115 / µm, so that from the center of the fiber core to the center of the active area 103 of the detector 65 a total tolerance of about t 265 / um.

Another aspect to be included in the analysis is the numerical aperture of the Fiber when the end of fiber 54 is the active area 103 is not close to each other. Light emerges from the fiber along a conical path that forms a the direction away from the end of the fiber increases. The numerical aperture refers to a characteristic the fiber that determines the angle of the conical path. Because the light spot size is in that of the fiber end As the direction away increases, one must consider the numerical aperture of the fiber and the distance from the end of the fiber of active area when choosing a fiber and detector. The window too has a refraction effect on the light path, which in Should be billed.

Given a fiber with a known core diameter and a known numerical aperture as well as with a given detector, one can calculate the light spot size in the active area of the detector and add to the total tolerance to give an effective light spot or light spot size obtain. This effective light spot size can then be determined using the specifications of the manufacturer of the detector in this way to ensure that the detector has an acceptable response shows. In a preferred embodiment, a cable was made from a single fiber having a core diameter of 200 / µm and a cladding diameter of 230 / µm,

sold under the trade designation HC-208-1U by Ensign-Bickford Co., Simsbury, Connecticut, completed with a contact ^ im Marketed under the trade name Amp 5 Optimate SMA Type Connector part number 227992-4 from Amp, Incorporated, Harrisburg, Pennsylvania. The detector used was under the trade name SD-3478 sold by Honeywell, Inc. of Richardson, Texas. The included in the connector according to the invention A combination of these components showed perfect operation in practice. However is the invention of course also with other combinations of fibers, contacts and detectors below Compliance with the principles given above is feasible.

The relatively small overall tolerance between the

Bores 89 and 66 are therefore possible, ^ hurry each rotary member 23 in the connector body 22 independently can move. The mobility of the rotating parts provides compensation for tolerances before, for example, the positional tolerance of the basic parts to one another, the positional tolerance of the basic module against the circuit board and the tolerance between the circuit board and the pivot arm. Be it notes that the latter tolerance between the circuit board and the pivot arm due to the Construction of the frame 12 can be relatively large. While looking at the dimensional deviation of the frame can restrict due to higher costs, such a restriction is not necessary because the rotating components can move and corresponding Afo measurement deviations can compensate.

The contact 51 is attached to the cable 25 in the field and the terminal end 52 is generally used as a step in the assembly of FIG polished to the specifications of the contact manufacturer

The distance between the terminal end 52 and the flange 56 of the contact can therefore be dependent be different from the amount of polishing · Normally the terminal end 52 of the contact would have to Touch window 100 of detector 65, and pretensioner 81 will be compressed or will just be on the verge of being squeezed. The terminal end 52 has been polished less and still has a sufficient finish, the pretensioner is compressed more. Became but the terminal end 52 is not polished enough and the finish of the end of the fiber is insufficient Losses so great that a good connection cannot be achieved. On the other hand, the connection end became stronger than recommended polished, it may happen that the connection end no longer touches the window of the detector. In this case, the base part 58 can press against the rotary member 23 and the axial movement of the Bring rotating component in the direction of the base to stop. While a little gap between that Connection end 52 and the window 100 of the detector 65 still ensure a sufficient optical connection can result in unacceptably high losses if the gap is too large. A larger gap also leads to that the end of the fiber farther away from the active area of the detector has a larger light spot the active area, so that possibly the allowable dimensional deviations between the Fiber core and the active area are exceeded.

As best seen in FIG. 1 and 2 it can be seen, the pivot arm 21 is in its establishing the connection Engaged or engaged position locked with the help of a swivel arm locking mechanism.

which includes a trap 108 formed at the upper or extended end of the connector body 22

is. A flexible pawl 109 is located at the lower end of an indicator light bank 110. The pawl 109 faces a notch 111 into which the latch 108 engages. To release you can bend the pawl 109 upwards, so that it disengages from the latch 108 and the pivot arm 21 from the engaged or switched-on position releases. The swivel arm locking mechanism can also serve to hold the circuit board 11 in the frame withhold when the pivot arm 21 is in its disengaged or disconnected position. To hold the circuit board in place 11 in the frame 12, however, other devices can also be provided, such as, for example from US Pat. No. 3,691,430.

As can also be seen from FIG. 1-3, the indicator light bank 110 is along the edge of the circuit board 11 mounted above the respectively assigned swivel arm 21. A group of status indicator lights 112 or other circuit elements, for example Trimmer potentiometers can be provided in the indicator lamp bank 110, with the advantage of that they are easily accessible and observable.

The described embodiment of the invention can be used in many ways within the scope of the invention Teaching can be modified. Thus, the invention can be applied not only to the single-fiber cables shown, but also to multi-fiber cables. Likewise, the contact used in the invention need not be frustoconical or tapered To have an end.

Claims (9)

Reicliel & Reicliel Parksirafie 13. . BQTOFrankfurt a.M. 1 οcnc ncη ALLEN-BRADLEY COMPANY. Milwaukee, ¥ iswonni »9 VStA patent claims 1. Connector for connecting one in an optical contact ending optical cable to a first photo transducer element, characterized by a rotating or pivoting component (23) for receiving the optical contact (51) in a bore (89) penetrating the pivoting component in the axial direction and for securely holding the contact (51) in such a way that the connecting end (52) of the contact (51 ) adjoins an inner side (91) of the pivot component (23), a connector body (22) with buckets formed therein cavity (74, 76) for loosely receiving the Pivoting component (23) such that the pivoting component (23) is freely movable within the cavity (74, 76), a base part (58) for fastening and holding the first photoconductor element (65) in such a way that the The photo transducer element (65) is accessible from an inner side (72) of the base part (58), on the inner side (91) of the pivoting component (23) and on the inner side (72) of the major part (58) formed mating surfaces (96, 98; 95, 97) for guiding the optical contact (51) and the first photoconductor element (65) in mutual alignment when the contact main piece (22) is in a the base part (58) adjoining the connection producing the connection position is brought, a biasing device provided between the connector main piece (22) and the pivot member (23) (81), which enables the self-alignment of the shoe component (23) allowed with the base part (58) and which presses the pivot component (23) in the direction of the base part (58), and Means (108, 109, 111) for securing the connector body (22) in the connection position that establishes the connection. 2. Connector according to claim 1,
characterized, that the base part (58) is attached to a circuit board (11, 64) and the circuit board in a frame (12) is mounted, and that the connector main piece (22) is pivotably connected to the frame (12) and between a disconnected position, in which the pivot component (23) is not in engagement with the base part (58), and the switched-on position is pivotable. 3. Connector according to claim 1 or 2, characterized in that that in the connector main piece (22) a plurality of pivoting components (23) and one for each pivoting component Pre-tensioning device (81) are accommodated, and that a similar plurality of base parts (58) each holding a first photoconductor element (65), is provided in a one-piece basic module. 20th 4. Connector according to one of the preceding claims, characterized in that that the connector main piece (22), the pivot component (23) and the base part (58) molded parts made of plastic are. 5. Connector according to one of the preceding claims, characterized by a transducer arrangement (24) with a) a second photo-transducer element (30), b) with the second photo-transducer element (30) connected electrical contact means (38) and c) devices (29, 55, 56) for connection an optical contact (51) to the second photo transducer element (30), and means (41, 48) provided on the connector body (22) for securing the transducer assembly (24). 6. Connector according to claim 5 » characterized, that the first photo transducer element (65) fastened in the base part (58) is an optoelectronic detector is and that the in the transducer arrangement (24) mounted second photo transducer element (30) is an optoelectronic Emitter is. 7. Connector for connecting an optical cable ending in an optical contact to a first photoconductor element, attached to a circuit board housed in a rack, characterized by one connected to the circuit board (11, 64) Base part (58) for attaching and holding the first photo transducer element (65) such that it is of a inner side (72) of the base part (58) is accessible, a rotating or pivoting component (23) for fastening and holding the optical contact (51) in such a way that the connecting end (52) of the optical contact (51) is adjacent to an inner side (91) of the pivoting component (23), a connector body (22) having a cavity (74, 76) formed therein for loosely receiving the Pivot member (23) such that it is within the connector body (22) is freely movable, means (17, 21) for pivotally connecting the connector body (22) with the frame (12) in such a way that by pivoting the connector main piece (22) the inner side (91) of pivot member (23) in general alignment with inner side (72) of frame member (58) is movable, formed on the inner side (91) of the pivot member (23) and on the inner side (72) of the base part (58), surfaces (96, 98; 95, 97) matched to one another for guiding the connecting end (52) of the optical Contact (51) and the first photo transducer element (65) in precise mutual alignment when the connector body (22) is pivoted into a connecting position producing the connection, a biasing device (81) provided between the connector main piece (22) and the pivot member (23), which presses the pivot component (23) in the direction of the base component (58) and which allows the pivot component (23) to to align itself accurately with the base member (58), and Means (108, 109, 111) for securing the connector body (22) in its connecting body Switch-on position. 8. Connector according to claim 7,
characterized, that the base part (58) with the circuit board (11, 64) is connected adjacent to an edge of the circuit board, that a portion of the edge of the circuit board (11, 64) with electrical contact pads (57) is provided, and that the following are also provided: a transducer arrangement (24) with a) a second photo transducer element (30), b) electrical contact means (38) connected to the second photo transducer element (30) and which are suitable for an easily detachable connection with the electrical contact pads (57), and c) devices (29, 55, 56) for connecting the optical contact (51) of the second photoconductor element (30), and means (41, 48) provided on the connector body (22) for securing the transducer assembly (24) to the electrical contact means (38) which act on the electrical contact pads (57) when the connector body (22) into its connection producing connection position is pivoted. 9. Connector according to claim 8, characterized in that in the connector body (22) a plurality of Pivoting components (23) and a pretensioning device (81) are provided for each pivoting component (23), that a similar plurality of base parts (58), each of which is a first photo-transducer element (65) supports, is formed on a one-piece base module (59), and that a plurality of transducer assemblies (24) along with a similar plurality of mounting devices (41, 48) for the transducer assemblies (24) are provided on the connector main piece (22).